CN105669185A - Low-dielectric-constant microwave dielectric ceramic Na2Zn2TiGeO7 and preparation method thereof - Google Patents
Low-dielectric-constant microwave dielectric ceramic Na2Zn2TiGeO7 and preparation method thereof Download PDFInfo
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Abstract
The invention discloses low-dielectric-constant microwave dielectric ceramic Na2Zn2TiGeO7 and a preparation method thereof. The preparation method comprises the steps that 1, chemical raw materials including Na2CO3, ZnO, TiO2 and GeO2 powder are weighed and blended according to the chemical stoichiometric equation Na2Zn2TiGeO7; 2, the raw materials in the step 1 are subjected to wet ball milling and mixing for 12 hours, distilled water serves as a ball milling medium, and the powder is pre-sintered for 6 hours in an air atmosphere at the temperature of 850 DEG C; 3, a binding agent is added to the powder obtained in the step 2, pelleting is carried out, then compression moulding is carried out, finally sintering is carried out for 4 hours in an air atmosphere at the temperature of 900 DEG C to 950 DEG C, a polyvinyl alcohol solution with the mass concentration of 5% serves as the binding agent, and the adding amount of polyvinyl alcohol accounts for 3% of the total mass of the powder. The ceramic is sintered well at the temperature of 1,000 DEG C or below, the dielectric constant ranges from 21.6 to 22.3, the quality factor Qf value of the ceramic reaches 64,200 GHz to 79,100 GHz, the temperature coefficient of resonance frequency is small, and the ceramic has high application value in industry.
Description
Technical field
The present invention relates to dielectric ceramic material, particularly relate to for manufacturing dielectric ceramic materials of microwave device such as the ceramic substrate of microwave frequency use, resonator and wave filter and preparation method thereof.
Background technology
Microwave dielectric ceramic refers to and is applied in microwave frequency band (mainly UHF and SHF frequency range) circuit as dielectric material the pottery completing one or more functions, modern communication is widely used as the components and parts such as resonator, wave filter, dielectric substrate and medium wave circuit, it it is the key foundation material of modern communication technology, in portable mobile phone, automobile telephone, wireless phone, television satellite accepter and military radar etc., there is highly important application, in the miniaturization of modern communication instrument, integrated process, just playing increasing effect.
It is applied to the dielectric ceramic of microwave frequency band, the requirement of following dielectric property should be met: (1) seriation DIELECTRIC CONSTANT εrTo adapt to different frequency and the requirement of different application occasion; (2) high quality factor q value or low dielectric loss tan δ, to reduce noise, generally require Qf >=3000GHz; (3) the temperature coefficient τ of resonant frequency?Little of as far as possible to ensure the heat stability that device has had ,-10ppm/ DEG C≤τ of general requirement?≤+10ppm/ DEG C. Just have tried to be applied to dielectric substance microwave technology in the world from late 1930s, and prepare TiO2Microwave dielectric filter, but its temperature coefficient of resonance frequency τ?Too greatly cannot be practical. Since the seventies in last century, start the large-scale development to medium ceramic material, according to relative dielectric constant εrSize different from what use frequency range, generally can will have been developed that and the microwave-medium ceramics developed be divided into 4 classes.
(1) ultralow dielectric microwave dielectric ceramic, main representative is Al2O3-TiO2、Y2BaCuO5、MgAl2O4And Mg2SiO4Deng, its εr≤ 20, quality factor q × f >=50000GHz, τ?≤ 10ppm/ ° of C. It is mainly used in microwave base plate and high-end microwave device.
(2) low εrWith the microwave dielectric ceramic of high q-factor, mainly BaO-MgO-Ta2O5,BaO-ZnO-Ta2O5Or BaO-MgO-Nb2O5,BaO-ZnO-Nb2O5System or the hybrid system MWDC material between them. Its εr=20~35, Q=(1~2) × 104(under f >=10GHz), τ?≈ 0.As dielectric resonance device in the microwave communication equipments such as the direct broadcasting satellite being mainly used in f >=8GHz.
(3) medium εrWith the microwave dielectric ceramic of Q-value, mainly with BaTi4O9、Ba2Ti9O20(Zr, Sn) TiO4Deng the MWDC material for base, its εr=35 ~ 45, Q=(6~9) × 103(under f=3~-4GHz), τ?≤ 5ppm/ ° of C. It is mainly used in the microwave military radar in 4~8GHz frequency range and in communication system as dielectric resonance device.
(4) high εrAnd the microwave dielectric ceramic that Q-value is relatively low, it being mainly used in 0.8~4GHz frequency range civilian mobile communcations system, this is also the emphasis of microwave dielectric ceramic research. Since the eighties, Kolar, Kato et al. find and have studied perovskite-like tungsten bronze type BaO Ln in succession2O3—TiO2Series (Ln=La, Sm, Nd or Pr etc. are called for short BLT system), complex perovskite structure CaO Li2O—Ln2O3—TiO2Series, lead base series material, Ca1-xLn2x/3TiO3It is contour εrMicrowave dielectric ceramic, wherein the BaO Nd of BLT system2O3—TiO2Material dielectric constant reaches 90, lead base series (Pb, Ca) ZrO3Dielectric constant reaches 105.
The sintering temperature of the above material system is generally greater than 1300 ° of C, it is impossible to directly and the low-melting-point metal such as Ag and Cu burn formation multilayer ceramic capacitor altogether. In recent years, along with LTCC Technology (LowTemperatureCo-firedCeramics, the requirement of development LTCC) and the development of microwave multilayer device, some low grade fever's system materials have been carried out exploring widely and research by research worker both domestic and external, mainly adopt devitrified glass or glassceramic composites system, have of a relatively high dielectric loss mutually because of low-melting glass, the existence of glassy phase substantially increases the dielectric loss of material. Therefore the emphasis that the low fired microwave dielectric ceramic material without glassy phase is current research is developed.
Can in the process of low fired microwave dielectric ceramic materials with development of new exploring, the material systems such as Li based compound, Bi based compound, tungstates architecture compound and tellurate architecture compound that intrinsic sintering temperature is low get the attention and research, but due to three performance indications (ε of microwave dielectric ceramicrWith Q f and τ?) between be that the relation of mutually restriction is (see document: the restricting relation between microwave dielectric ceramic materials dielectric properties, Zhu Jianhua, Liang Fei, Wang little Hong, Lv Wenzhong, electronic component and material, phase March the 3rd in 2005), meet three performance requirements and the single-phase microwave-medium ceramics of low temperature sintering be considerably less, mainly their temperature coefficient of resonance frequency generally excessive or quality factor are on the low side and cannot application request. Research major part to microwave-medium ceramics is the summary of experience drawn by great many of experiments at present, but there is no complete theory to set forth the relation of microstructure and dielectric properties, therefore, in theory also its microwave dielectric property such as temperature coefficient of resonance frequency and quality factor be cannot predict from the composition of compound and structure, low temperature co-fired technology and the development of microwave multilayer device which greatly limits. Explore and low-temperature sintering can have near-zero resonance frequency temperature coefficient (-10ppm/ DEG C≤τ with exploitation simultaneously?≤+10ppm/ DEG C) it is that those skilled in the art thirst for solving always but are difficult to the difficult problem succeeded all the time with the microwave dielectric ceramic of higher figure of merit.
Summary of the invention
It is an object of the invention to provide the application as dielectric constant microwave dielectric ceramic of a kind of composite oxides and the method preparing this microwave dielectric ceramic.This microwave dielectric ceramic has good heat stability and low-loss, simultaneously can low-temperature sintering.
The chemical composition of the microwave dielectric ceramic material of the present invention is Na2Zn2TiGeO7。
The preparation method step of this microwave dielectric ceramic material is:
(1) by chemical raw material Na2CO3、ZnO、TiO2And GeO2Powder is formula Na stoichiometrically2Zn2TiGeO7Weigh dispensing.
(2) by step (1) raw material wet ball-milling mix 12 hours, ball-milling medium is distilled water, after drying in 850 DEG C of air atmosphere pre-burning 6 hours.
(3) after adding binding agent pelletize in the powder that step (2) prepares, more compressing, finally sinter 4 hours in 900 ~ 950 DEG C of air atmosphere; Described binding agent adopts mass concentration to be the poly-vinyl alcohol solution of 5%, and polyvinyl alcohol addition accounts for the 3% of powder gross mass.
Advantages of the present invention: Na2Zn2TiGeO7Ceramic sintering temperature is low, and cost of material is low; Dielectric constant reaches 21.6~22.3, the temperature coefficient τ of its resonant frequency?Little, temperature stability is good; Quality factor q f value, up to 64200-79100GHz, can be widely used for the manufacture of the microwave devices such as various medium substrate, resonator and wave filter, can meet the technology needs of low temperature co-fired technology and microwave multilayer device.
Detailed description of the invention
Embodiment:
Table 1 illustrates 3 specific embodiments and the microwave dielectric property thereof of the different sintering temperatures constituting the present invention. Its preparation method as it has been described above, carry out the evaluation of microwave dielectric property by cylindrical dielectric resonator method; Adopting X-ray diffraction analysis to carry out material phase analysis, all samples is one-component ceramic.
This pottery can be widely used for the manufacture of the microwave devices such as various medium substrate, resonator and wave filter, can meet the technology needs of the system such as mobile communication and satellite communication.
Table 1:
Claims (1)
1. composite oxides are as the application of dielectric constant microwave dielectric ceramic, it is characterised in that the chemical composition of described microwave dielectric ceramic is: Na2Zn2TiGeO7, its dielectric constant is 21.6 ~ 22.3, and temperature coefficient of resonance frequency is 9ppm/ DEG C;
The preparation method of described microwave dielectric ceramic concretely comprises the following steps:
(1) by chemical raw material Na2CO3、ZnO、TiO2And GeO2Powder is formula Na stoichiometrically2Zn2TiGeO7Weigh dispensing;
(2) by step (1) raw material wet ball-milling mix 12 hours, ball-milling medium is distilled water, after drying in 850 DEG C of air atmosphere pre-burning 6 hours;
(3) after adding binding agent pelletize in the powder that step (2) prepares, more compressing, finally sinter 4 hours in 900 ~ 950 DEG C of air atmosphere; Described binding agent adopts mass concentration to be the poly-vinyl alcohol solution of 5%, and polyvinyl alcohol addition accounts for the 3% of powder gross mass.
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CN112408980A (en) * | 2020-10-31 | 2021-02-26 | 桂林理工大学 | Low-dielectric-constant microwave dielectric ceramic with adjustable resonant frequency temperature coefficient and preparation method thereof |
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CN104692793A (en) * | 2015-02-05 | 2015-06-10 | 桂林理工大学 | Temperature-stable low-dielectric constant microwave dielectric ceramic Li2ZnTi5O12 and preparation method thereof |
CN105294075A (en) * | 2015-11-29 | 2016-02-03 | 桂林理工大学 | High-quality-factor temperature-stable microwave dielectric ceramic Li2ZnGe2O6 and preparation method thereof |
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CN104692793A (en) * | 2015-02-05 | 2015-06-10 | 桂林理工大学 | Temperature-stable low-dielectric constant microwave dielectric ceramic Li2ZnTi5O12 and preparation method thereof |
CN105294075A (en) * | 2015-11-29 | 2016-02-03 | 桂林理工大学 | High-quality-factor temperature-stable microwave dielectric ceramic Li2ZnGe2O6 and preparation method thereof |
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CN112408980A (en) * | 2020-10-31 | 2021-02-26 | 桂林理工大学 | Low-dielectric-constant microwave dielectric ceramic with adjustable resonant frequency temperature coefficient and preparation method thereof |
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